Zebrafish teach researchers more about atrial fibrillation
Genetic research in zebrafish at the University of Copenhagen has surprised the researchers behind the study. The results have the potential to change the prevalent perception of the cardiac disorder atrial fibrillation.
Researchers from the Faculty of Health and Medical Sciences have shown a possible link between a genetic variation and the widespread type of cardiac arrhythmia, atrial fibrillation.
Facts: Atrial fibrillation
- Atrial fibrillation, or AF, is the most common form of cardiac arrhythmia.
- Atrial fibrillation triggers electrical impulses from atypical locations in the anterior chamber, often much faster than usual. This interferes with the contraction of the heart and thus the pumping function.
- The affliction affects 2-3 percent of all people and results in significantly increased morbidity and mortality.
- The most common symptoms are discomfort in the chest, palpitations and shortness of breath. Long-term arrhythmia is associated with an increased risk of stroke and heart failure.
- New research from the University of Copenhagen shows that atrial fibrillation is not only an electrical disorder, but also has a genetic and muscular component.
The scientists conducted the study in zebrafish, which is a recognised scientific animal model within cardiac research.
Here, researchers from the University of Copenhagen put special focus on the gene pitx2c, and the result came as a surprise to them, says Assistant Professor Pia Lundegaard from the Department of Biomedical Sciences.
‘It seems that we may also have to think of atrial fibrillation as an atrial cardiomyopathy – that is, a challenged heart – rather than as a purely electrical disorder’, she says.
Defects in muscle fibres and mitochondria
Contrary to expectations, the researchers did not find any disturbances in the ion channels that spread electrical signals between the heart's muscle cells.
The rhythm disorder may be secondary to what is actually the problem.
Instead, they found defects in the structure of the heart muscle itself and in the mitochondria that normally function as the cell's power plant. The defects already occurred in the foetal stage of the fish and deteriorated exponentially with age.
‘Usually the structure of a cross-section of the sarcomeres – the muscle fibres – shows a very fine grid structure. But in these fish, it is clear that the structure is disorganised from a very early stage’, explains Pia Lundegaard, adding:
‘At the same time, we can see in our pictures that there are too many mitochondria. So, it seems that the heart is trying to compensate for the defective muscle fibres. This indicates that there is a structural defect in the heart which over time will cause a rhythm defect’.
Antioxidant prevents defects
According to the research study, the increased number of mitochondria appears to aggravate the negative spiral, the reason being that also the mitochondria are defective and gradually increase the level of so-called oxidative stress.
In other words, they create an unhealthy environment in the cell where different proteins are broken down.
At the same time, however, the researchers found that early and ongoing treatment with the antioxidant NAC seemed to counteract the defect and in the long term prevent atrial fibrillation in the fish.
However, Pia Lundegaard from the Department of Biomedical Sciences emphasises that heart patients should not stockpile antioxidants such as NAC for that reason.
She points out that the studied gene is just one of many possible factors behind atrial fibrillation, which is also greatly influenced by the individual's lifestyle.
In addition, to better demonstrate the effect of the studied gene, the gene defect has been designed to be stronger in the test fish than commonly seen in humans.
Better control procedures
The improved understanding of the disease nevertheless provides greater insight into the reason why some atrial fibrillation medications may not always work as well as one might wish.
It seems that we may also have to think of atrial fibrillation as an atrial cardiomyopathy – that is, a challenged heart.
Therefore, Pia Lundegaard hopes that the result of the new research will be that more practitioners reconsider the possible causes behind rhythm disorders.
‘The rhythm disorder may be secondary to what is actually the problem. We hope that in the future, we can develop better control procedures that will prevent some people's hearts from being worn down for a long time and eventually fail’, she says.
The next step for the research group is to investigate other genes associated with atrial fibrillation. Likewise, the group will investigate whether antioxidants other than NAC can prevent the disorder.
About the study
The study ‘Early sarcomere and metabolic defects in a zebrafish pitx2c cardiac arrhythmia model’ has been published in the scientific journal PNAS.
The findings are the result of a collaboration between the University of Copenhagen and the German Max Planck Institute in Bad Neuheim. Two German foundations as well as the Danish John and Birthe Meyer Foundation and the Novo Nordisk Foundation supported the study.
Assistant Professor Pia Rengtved Lundegaard
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Communications Officer Anders Buch-Larsen